Doris Apt

Overcoming antigenic diversity and improving vaccines using DNA shuffling and screening technologies

Viral, bacterial and parasitic pathogens have evolved multiple strategies to evade the immune response, facilitate transmission and establish chronic infections. One of the underlying strategies that pathogens have evolved is antigenic variation of immune response targets that reduce the affinity of antigen binding to antibodies and major histocompatability complex class I and II receptors. Vaccine candidates generally target a limited number of these antigen variants or combine antigens from several variants to include in multivalent vaccine formulations. DNA shuffling and screening technologies, also known as MolecularBreedingTM (Maxygen, Inc.) directed molecular evolution, have been successfully used to identify and develop novel and chimaeric vaccine candidates capable of inducing immune responses that recognise and control multiple antigenic variants. DNA shuffling and screening strategies also select vaccine candidates with improved immunogenicity, increased expression as recombinant polypeptides and improved growth of whole viruses in cell culture. As DNA shuffling and screening strategies can be applied to many pathogens, there remain numerous applications of DNA shuffling to solve challenging problems in vaccine process development and manufacture.

EpCAM-specific vaccine response by modified antigen and chimeric costimulatory molecule in cynomolgus monkeys.

Immunization against tumor-associated antigens is a promising approach to cancer therapy and prevention, but it faces several challenges and limitations, such as tolerance mechanisms associated with self-antigens expressed by the tumor cells. Costimulatory molecules B7.1 (CD80) and B7.2 (CD86) have improved the efficacy of gene-based and cell-based vaccines in animal models and are under investigation in clinical trials. However, their efficacy as vaccine adjuvants is likely limited by the fact that they mediate both stimulatory and inhibitory signals to T cells via CD28 and CTLA-4, respectively. To overcome these limitations, we have generated a B7.1-like, chimeric costimulatory molecule with preferential binding to CD28, named CD28-binding protein (CD28BP), which we combined with a modified, nonself tumor antigen variant of epithelial cell adhesion molecule (EpCAM), named TAg25. TAg25 induced a cross-reactive immune response against human wild-type EpCAM upon DNA vaccination in cynomolgus monkeys. However, TAg25 DNA immunization alone or in combination with human (h) B7.1 induced no detectable antigen-specific T cells in the peripheral blood of the animals. In contrast, TAg25 combined with CD28BP induced both CD4+ and CD8+ T cells specific for EpCAM. Moreover, TAg25 combined with CD28BP induced significantly higher levels of EpCAM-specific antibodies than TAg25 plus hB7.1. These improved adjuvant properties of CD28BP, when compared with hB7.1, illustrate the importance of CD28 costimulation in vaccine responses in nonhuman primates and warrant further studies on the potential of CD28BP in improving the efficacy of cancer vaccines.